Vascularized tissue engineering of vital organs: design, modeling and functional testing

Author

Kaazempur-Mofrad, M.R. ; Borenstein, J.T. ; Hartman, L.M. ; Cheung, W.S. ; Weinberg, E.J. ; Shin, M. ; Sevy, A. ; Vacanti, J.P.

Author_Institution

Dept. of Surg., Harvard Med. Sch., Boston, MA, USA

fYear

2003

Firstpage

205

Lastpage

206

Abstract

We report engineering of vascularized tissue constructs for the replacement of vital organ function. A computational algorithm for simulation of blood flow and rheology in microcirculation is developed and utilized to design fractal microvascular networks that mimic the key features of vital organ´s blood supply. Using microfabrication/polymer processing technologies, these designed microvascular networks are replica molded to generate patterned biopolymer films, which are then stacked to form alternating vascular and parenchymal compartments. As our preliminary functional tests demonstrate, this approach is promising to produce viable liver and kidney tissues.

Keywords

biological organs; blood vessels; fractals; haemorheology; kidney; liver; microfluidics; physiological models; MEMS; blood flow simulation; blood supply key features; computational algorithm; donor organs shortage; fractal microvascular networks design; functional tests; microfabrication; parenchymal compartment; patterned biopolymer films generation; replica molding; vascular compartment; vascularized tissue engineering; Algorithm design and analysis; Blood flow; Computational modeling; Computer networks; Fractals; Polymer films; Process design; Rheology; Testing; Tissue engineering;

fLanguage

English

Publisher

ieee

Conference_Titel

Bioengineering Conference, 2003 IEEE 29th Annual, Proceedings of

Print_ISBN

0-7803-7767-2

Type

conf

DOI

10.1109/NEBC.2003.1216065

Filename

1216065